Factores nutricionales y alteración en el contenido de antocianinas relacionados con el ennegrecimiento de los pétalos en rosa (Rosa sp.)

Nutritional factors and modification in the content of anthocyanins associated with the blackening of rose petals (Rosa sp.)

Contenido principal del artículo

Wilson Bohórquez
John Gómez
Víctor Flórez

Resumen

Uno de los desórdenes fisiológicos más importantes en los cultivares de rosa roja corresponde al ennegrecimiento de los pétalos, lo que afecta pétalos externos e internos y resulta en flores de baja calidad. Esta revisión de literatura tiene por objetivo abordar la fisiopatía del ennegrecimiento de los pétalos, desde sus causas más posibles, con la finalidad de poner a disposición de productores, de académicos y de científicos, así como de los interesados en general, insumos que permitan desvendar su origen y optimizar su manejo. Los síntomas del ennegrecimiento de los pétalos se manifiestan, especialmente, cuando las flores son cosechadas y almacenadas en condiciones de cuarto frío, debido a la acumulación de pigmentos del tipo de las antocianinas, posiblemente, a causa de condiciones de estrés, como alta o baja radiación UV, bajas temperaturas o a un desbalance de nutrientes en los tejidos afectados. Se profundizará sobre: i) los nutrientes calcio y boro y su interacción, ii) el calcio y los desórdenes fisiológicos, iii) los pigmentos involucrados en el color rojo de los pétalos y iv) el papel de los compuestos fenólicos, en particular de las antocianinas, las cuales, son las responsables de la mayoria de los colores rojo, rosado, purpura y azul observados en las partes de la planta; así como, sobre factores ambientales que, en su conjunto, pudieran influir en la fisiopatía del ennegrecimiento de los pétalos de la rosa roja.

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APOSTOL, K.; ZWIAZEK, J. 2004. Boron and water uptake in jack pine (Pinus Banksiana) seedlings. Environ. Exp. Bot. 51(2):145-153.

BLOWERS, D.P.; TREWAVAS, A.J. 1988. Phosphatidylinositol kinase activity of a plasma membraneassociated calcium-activated protein kinase from pea. Fed. Eur. Biochem. Soc. 238(1):87-89.

BLEVINS, D.; LUKASZEWSKI, K. 1998. Boron in plant structure and function. Ann. Rev. Plant Physiol. 49:481-500.

BOLAÑOS, L.; LUKASZEWSKI, K.; BONILLA, I.; BLEVINS, D. 2004. Why boron? Plant Physiol. Biochem. 42(11):907-912.

BOROCHOV, A.; MAYAK, S.; BROUN, R. 1982. The involvement of water stresses and ethylene in senescence of carnation flowers. J. Exp. Bot. 33:1202-1209.

BROUILLARD, R. 1988. The Flavonoids: Advances in research. In: Harborne, J.B. (Ed.). Flavonoids and flower color. Chapman & Hall, (London). p.525-538.

CABRERA, R.I.; SOLÍS-PÉREZ, A.R.; McCORMICK, J. 2007. The role of calcium and boron in rose development and petal blackening: Observations in commercial rose greenhouses and shoot tissue nutrient status. Progress Report (July to December). Texas A&M University. Research and Extension Center. 5p.

CARA, F.; SÁNCHEZ, E.; RUIZ, J.; ROMERO, L. 2002. Is phenol oxidation responsible for the short term effect of boron deficiency on plasma-membrane permeability and function in squash root? Plant Physiol. Biochem. 40(10):853-858.

CHEN, Q.; YU, H.; TAN, H.; WANG, X. 2012. Identification and expression analysis of genes involved in anthocyanin and proanthocyanidin biosynthesis in the fruit of blackberry. Sci Hort. 141:61-68.

CHIU, T.F.; BOULD, C. 1976. Effects of shortage of calcium and other cation on Ca mobility, growth and nutritional disorders of tomato plants (Lycopersicon esculentum). J. Sci. Food Agr. 27:969-977.

COLLIER, G.F.; HUNTINGTON, V.C. 1983. The relationship between leaf growth, calcium accumulation and distribution, and tipburn development in field grown butterhead lettuce. Sci. Hortic. 21(2):123-128.

CRESSWELL, G.C.; WEIR, R.G. 1997. Plant Nutrient Disorders 5: Ornamental Plants and Shrubs. Inkata Press, Melbourne. 234p.

EPSTEIN, E. 1973. Flow in the phloem and the immobility of calcium and boron: A new hypothesis in support of an old one. Experienta. 29:133-136.

FLETCHER, R.; GILLEY, A.; SANKHLA, N.; DAVIS, T. 2000. Triazoles as plant growth regulator and stress protectants. Hort. Rev. 24:55-138.

FRANCO, J.A.; PEREZ-SAURA, P.J.; FERNANDEZ, J.A.; PARRA, M.; GARCIA, A.L. 1999. Effect of two irrigation rates on yield, incidence of blossom-end rot, mineral content, and free amino acid levels in tomato cultivated under drip irrigation using saline water. J. Hort. Sci. & Biotechn. 74:430-435.

FRANCK, C.; LAMMERTYN, J.; HO, Q.T.; VERBOVEN, P.; VERLINDEN, B.E.; NICOLAI, B.A. 2007. Review: Browning disorders in pear fruit. Posth. Biol. Techn. 43:1-13.

GRATTAN. S.; GRIEVE, C. 1999. Salinity-mineral nutrient relations in horticultural crops. Sci. Hort. 78:127-157.

GRIESBACH, R.J. 1992. Correlation of pH and light intensity on flower color in potted Eustoma grandiflorum Grise. Hort. Sci. 27(7):817-818.

GROTEWOLD, E. 2006. The genetics and biochemistry of floral pigments. Ann. Rev. Plant Biol. 57:761-780.

GRUNZWEIG, J.; RABINOWICH, H.; KATAN J.; WODNER, M.; BENTAL, Y. 2000. Involvement of endogenous gibberellins in the regulation of increased tomato shoot growth in solarized soil. Plant Growth Reg. 30:233-239.

HADI, M.; CONWAY, W.; SAM, C. 1996. Effect of calcium on yield and incidence of blossom-end rot of three tomato cultivars. J. Hort. Sci. 31:672-679.

HALEVY, A.; ZIESLIN, N. 1974. The development and causs of petal blackening and malformation of "Baccara" rose flower. Acta Hort. 14:149-155.

HAMAUZU, Y.; HANAKAWA, T. 2003. Relation of highly polymerised procyanidin to the potential browning susceptibility in pear fruits. J. Jap. Soc. Hort. Sci. 72:415-421.

IGLESIAS, J.; GRAELI, G.; ECHEVERRIA, M.; VENDRELL. 1999. Differences in fruit color development, anthocyanin content, yield and quality of seven delicious apple strains. Fruit Var. J. 53(1):133-145.

ISHII, T.; MATSUNAGA, T. 2001. Pectic polysaccharide rhamnogalacturonan II is covalently linked to homogalacturonan Phytochem. 57:969-974.

ITZHAKI, H.; NAVEH, L.; LINDAHL, M.; COOK, M.; ADAM, Z. 1998. Identification and characterization of DegP, a serine protease associated with the lumenal side of the thylakoid membrane. J. Biol. Chem. 273:7094-7098.

JAFFRIN, A. 2002. Ennegrecimiento de los pétalos de rosas bajo diferentes tipos de invernadero. Plasticulture. 121(3):12-21.

JAKOPIC, J.; STAMPAR, F.; VEBERIC, R. 2009.The influence of exposure to light on the phenolic content of ‘Fuji' apple. Sci. Hort. 123:234-239.

JENKINS, G.I.; CHRISTIE, J.M.; FUGLEVAND, G.; LONG, J.C.; JACKSON, J.A. 1995. Plant responses to UV and blue light: Biochemical and genetic approaches. Plant Sci. 112:117-138.

KARABAL, E.; YÜCEL, M.; AVNI, H. 2003. Antioxidant responses of tolerant and sensitive barley cultivars to boron toxicity. Plant Sci. 164 (6):925-933.

KIM, D.; BAE, J.; LEE. D.; LEE, H.; JOO, M.; YOO, S. 2011. Positive effects of glycosylated anthocyanin isolated from an edible berry fruit (Acanthopanax sessiliflorum) on its antioxidant activity and color stability. Food Res. Int. 44:2258-2263.

LEE, J.; LEE, H.; CHOUNG, M. 2011. Anthocyanin compositions and biological activities from the red petals of Korean edible rose (Rosa hybrida cv. Noblered). Food Chem. 129:272-278

LEE, J., RENNAKER, C.; WROLSTAD, R.E. 2008. Correlation of two anthocyanin quantification methods: HPLC and spectrophotometric methods. Food Chem. 110:782-786.

LEE, J.; DURST, R.W.; WROLSTAD, R.E. 2005. Determination of total monomeric anthocyanin pigment content of fruit juices, beverages, natural colorants, and wines by the pH differential method: Collaborative study. J. AOAC Int. 88(5):1269-1278.

LEGUIZAMÓN, G.V.; GONZALEZ, L.A.; BAEZ, S.R. 2005. Grape anthocyanins (Vitis vinifera L.) and their relation to color. Rev. Fitotec. Mex. 28(4):359- 368.

LEHTO, T.; RÄISÄNEN, M.; LAVOLA, A.; JULKUNENTITTO, R.; APHALO, P. 2004. Boron movility in deciduos forest trees in relation to their polyls. New Phytol. 163:333-339.

LIANG, W.J.; WANG, M.L.; AI, X.Z. 2009. The role of calcium in regulating photosynthesis and related physiological indexes of cucumber seedlings under low light intensity and suboptimal temperature stress. Sci. Hort. 123:34-38.

LU, Y.; DU, J.; TANG, J.; WANG, F.; ZHANG, J.; HUANG, J.; LIANG, W.; WANG, L. 2009. Environmental regulation of floral anthocyanin synthesis in Ipomoea purpurea. Molec. Ecol. 18:3857-3871.

MARKOVIC, D.J.; NADEZJDA, J.; PETRANOVIC, A.; BARANAC, J.M. 2005. The copigmentation effect of sinapic acido on malvidin: a spectroscopic investigation on color enhancement. J. Photochem. Photobiol. B, Biol. 78(3):223-228.

MARSCHNER, H. 1995. Mineral nutrient of higher plants, 2nd. ed. Academic Press (London). 446p.

MARSCHNER, H. 1983. General introduction to the mineral nutrition of plants. In: Läuchli, A.; Bieleski, R.L. (eds.) Encyclopedia of Plant Physiology, New Series, Vol. 15A. Springer-Verlag (Berlin). p.5-60.

MARTYN, A.; THOMAS, CH.; O'NEILL, M.; OFFORD, C.; McCONCHIE, R. 2007. Bract browning in waratahs (Telopea spp.) is not a localized calcium deficiency disorder. Sci. Hort. 112:434-438.

MARTYN, A.; GOLLNOW, B.; McCONCHIE, R.; OFFORD, C. 2007. Characterization of bract browning and the effect of shade on browning in waratah (Telopea spp., Proteaceae) cultivars ‘Fire and Brimstone', ‘Olympic Flame' and ‘Wirrimbirra White'. Sci. Hort. 112:427-433.

MOL, J.; JENKINS, G.; SCHAFER, E.; WEISS, D. 1996. Signal perception, transduction, and gene expression involved in anthocyanin biosynthesis. Crit. Rev. Plant Sci. 15:525-557.

MURRAY, S.A.; SPURR, A.R.; PAULSON, K.N. 1972. Electron probe analysis of Ca, Mg and K in the fruit of the tomato, Lycopersicon esculentum, with reference to blossom-end rot. Agr. J. 64(5):586-588.

O'NEILL, S.; GOULD, S.K. 2003. Anthocyanis in leave: light attenuators or antioxidants? Func. Plant Biol. 30:865-873.

PALZKILL, D.A.; TIBBITTS, T.W.; STRUCKMEYER, B.E. 1980. High relative humidity promotes tipburn on young cabbage plants. HortSci. 15:659-660.

PETRONI, K.; TONELLI, Ch. 2011.Recent advances on the regulation of anthocyanin synthesis in reproductive organs. Ann. Rev. Plant Sci. 181:219-229

PFEFFER, H.; DANNEL, F.; RÖMHELD, V. 2001. Boron compartmentation in root sunflower: A study using the stable isotopes 10B and 11B adopting two independent approaches. Physiol. Plant. 113:346-351.

PINTER, J.; KÓSA, E.; HADI, G.; HÉGYI, Z.; SPITKO, T., TOTH, Z.; SZIGETI, Z.; PALDI, E.; MARTON, C. 2007. Effect of increased UVradiation on the anthocyanin content of maize (Zea mays L) leaves. Acta Agr. Hung. 55(1):7-17.

POOVAIAH, B.W. 1988. The molecular and cellular aspects of calcium action. HortSci. 23:267-271.

QUINTANA, A.; JANA ALBRECHTOVA, J.; GRIESBACH, R.; FREYRE, F. 2007. Anatomical and biochemical studies of anthocyanidins in flowers of Anagallis monelli L. (Primulaceae) hybrids. Sci. Hort. 112:413-421.

RAHMAN, M.; PUNJA, Z. 2007. Calcium and plant disease. In: Datnoff, L.E.; Elmer, W.H., and Huber, D.M. (eds).Mineral Nutrition and Plant disease. The American Phytopathological Society. Ed. APS Press (St. Paul). 7993p.

REUTER, D.J.; ROBINSON, J.B. 1986. Plant Analysis: An Interpretation Manual. Ed. Inkata Press (Melbourne). 218p.

RODRIGUEZ-SAONA, L.E.; WROLSTAD, R.E. 2001. Extraction, isolation and purification of anthocyanins. Current Protocols in Food Analytical Chemistry. John Willey and Sons. Inc. 11p.

ROUX, S.J.; SLOCUM, R.D. 1982. Role of calcium in mediating cellular functions important for growth and development in higher plants. In: Cheung, W. Y. ed. Calcium and cell function, Vol III. Academic Press (New York), p.408-453.

RUIZ, J.; BRETONES, G.; BAGHOUR, M.; RAGALA, L.; BELAKBIR, A.; ROMERO, L. 1998. Relationship between boron and fenolic metabolism in tobacco leaves. Phytochem. 48(2):269-272.

SAITO, N.; TATSUZAWA, F.; TOKI, K.; SHINODA, K.; SHIGIHARA, A.; HONDA, T. 2011. The blue anthocyanin pigments from the blue flowers of Heliophila coronopifolia L. (Brassicaceae). Phytochem.72:2219-2229.

SAURE, M. 1998. Causes of the tipburn disorder in leaves of vegetables. Sci. Hort. 76:131-147.

SAURE, M. 2001. Blossom-end rot of tomato (Lycopersicon esculentum Mill.) a calcium - or a stress-related disorder? Sci. Hort. 90:193-208.

SCHMITZER, V.; OSTERC, G.; VEBERIC, R.; STAMPAR, F. 2009. Correlation between chromaticity values and major anthocyanins in seven Acer palmatum Thunb. cultivars. Sci. Hort. 119:442-446.

SCHMITZER, V.; VEBERIC, F.; STAMPAR, F. 2012. Pro- hexadione-Ca application modifies flavonoid composition and color characteristics of rose (Rosa hybrida L.) flowers. Sci Hort. 146:14-20.

STEYN, W.J.; HOLCROFT, D.M.; WAND, S.J.E.; COOKS, N.C.; JACOBS, G. 2000. Dating Rosemarie: How to make her blush?. Proceedings of the cape Pomolological association Symposium. South Africa. p.55-62.

TAIZ, L.; ZEIGER, E. 2006. Plant Physiology. 3rd edition, Sinanuer Associate, Inc. (USA). 690p.

TATSUZAWA, F.; ICHIHARA, K.; SHINODA, K.; MIYOSHI, K. 2010. Flower colours and pigments in Disa hybrid (Orchidaceae). South Afr. J. Botany. 76:49-53.

TORRE, S.; BOROCHOV, A.; HALEVY, A.H. 1999. Calcium regulation of senescence in rose petals. Phys. Plant. 107:214-219.

WANGA, B.; HEA, J.; DUANB, Ch.; YUA, X.; ZHUA, L.; XIEA, Z.; ZHANGA, C.; XUA, W.; WANG, S. 2012. Root restriction affects anthocyanin accumulation and composition in berry skin of ‘Kyoho' grape (Vitis vinifera L. × Vitis labrusca L.) during ripening. Sci Hort. 137:20-28.

WISSEMEIER, A.H. 1996. Calcium-Mangel bei Salat (Lactuca sativaL.) und Poinsettie (Euphorbia pulcherrima Willd. ex Klotzsch): Einfluß von Genotyp und Umwelt. Verlag Ulrich E. Grauer (Stuttgart). 299p.

WISSEMEIER, A.H. 1993. Marginal bract necrosis in Poinsettia cultivars and the relationship to bract calcium nutrition. Gartenbauwiss. 58:158-163.

WEISS, D. 2000. Regulation of flower pigmentation and growth: Multiple signaling pathways control anthocyanin synthesis in expanding petals. Phys. Plant. 110:152-157.

WHITTAKER, A.; VAZZANA, C.; VECCHIO, V.; BENEDETTELLI, S. 2009. Evaluation of direct and indirect effects of flavonoids, mineral elements and dry weight on antiradical scavenging activity in leaf material of field-grown Trifolium pratense cultivars using Path Analysis. Field Crops Res. 113:1-11.

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